Mercury methylation genes in bacteria and archaea

ABSTRACT

Two genes required for this mercury methylation have been identified in bacteria and archaea. These genes are the hgcA gene and hgcB, a corrinoid protein that facilitates methyl group transfer to Hg, and a corrinoid protein-associated ferredoxin with two [4Fe-4S] binding motifs involved in generating cob(I)almin, respectively. The invention provides nucleic acid probes and primers for detecting methylmercury and or for assessing mercury methylation potential in environmental, clinical and other samples. The invention also provides antibodies against these proteins, antibodies against these proteins, methods of using the antibodies and methods of biocatalysis.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims benefit of U.S. Provisional Application No. 61/739,302, filed on Dec. 19, 2012, which is incorporated herein by reference in its entirety.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH

This invention was made with government support under Prime Contract No. DE-AC05-00OR22725 awarded by the U.S. Department of Energy. The government has certain rights in the invention.

SEQUENCE LISTING

The instant application contains a Sequence Listing which has been submitted electronically in ASCII format and is hereby incorporated by reference in its entirety. Said ASCII copy, created on Dec. 13, 2013, is named 28804_SL.txt and is 60,572 bytes in size.

FIELD OF THE INVENTION

Methylmercury is a potent, bioaccumulative neurotoxin produced by microorganisms from inorganic Hg(II). Two genes required for this conversion have been identified in both bacteria and archaea. These genes are the hgcA gene which encodes a corrinoid protein that facilitates methyl group transfer to Hg, and the hgcB gene which encodes a corrinoid protein-associated ferredoxin with two [4Fe-4S] binding motifs and are involved in generating to cob(I)almin. Both genes have been found in methylating strains but not in non-methylating strains (with available genomic sequences). Their deletion abolished mercury methylation activity in Desulfovibrio desulfuricans ND132 and Geobacter sulfurreducens PCA and complementation restored activity.

BACKGROUND OF THE INVENTION

Mercury is a pervasive global pollutant which bioaccumulates in the food web and is highly toxic to humans and other organisms. Anaerobic microorganisms, such as sulfate-reducing bacteria (SRB), iron-reducing bacteria and methanogens have been implicated as producers of methylmercury (MeHg). However, phylogenetic analyses based on 16S sequences cannot distinguish between methylating and non-methylating microorganisms (Ranchou-Peyruse 2009; Gilmour 2011; Yu et al. 2012).

Biological mercury methylation was shown to be an enzyme-catalyzed process and proposed to be associated with the reductive acetyl-CoA (Wood-Ljungdahl) pathway (Wood 1968; Choi 1994b). A 40 kDa corrinoid-binding protein capable of methylating mercury was identified in cell extracts of the sulfate-reducing bacterium Desulfovibrio desulfuricans LS—a methylating SRB strain. Unfortunately, the strain was lost and further characterization of that 40 kD protein is not possible (Gilmour 2011). Although mercury methylation activity was proposed to be associated with the reductive acetyl-CoA (Wood-Ljungdahl) biochemical pathway (Choi et al. 1994a), no consistent relationship was ever established between that pathway and the ability to methylate Hg(II), suggesting the existence of an alternative, but as yet unidentified, pathway or pathways to form MeHg in microorganisms (Ekstrom 2003).

Accordingly, the need remained to understand the genetic and biochemical basis for microbial mercury methylation and to identify specific microorganisms with the potential to methylate mercury. The availability of the complete genome sequences for known mercury methylators and non-methylators aided the discovery, identification and characterization of two genes and their gene products, associated with a mercury methylation pathway common to all known methylating bacteria and archaea sequenced to date. Characterization of these gene products explains mercury methylation in microorganisms whether or not the complete acetyl-CoA pathway is present in those microorganisms. Moreover, the availability of the genes provides a biomarker for microbial mercury methylation that can be used to identify methylators as well as to assess the mercury methylation potential.

SUMMARY OF THE INVENTION

The present invention is directed to isolated nucleic acids for hgcA or hgcB, genes that encode products that catalytically cycle to methylate mercury. In particular, the isolated nucleic acids include, but are not limited to, contiguous nucleotides for hgcA shown in FIG. 5, a nucleotide sequence encoding the amino acid sequence for HgcA shown in FIG. 5, a nucleotide sequence encoding an amino acid sequence for HgcA from any one of the microorganisms listed in Table 1, or a consensus nucleotide sequence that detects hgcA from microorganisms capable of mercury methylation.

The isolated nucleic acids of the invention also include, but are not limited to, contiguous nucleotides for hgcB shown in FIG. 6, a nucleotide sequence encoding the amino acid sequence for HgcB shown in FIG. 6, a nucleotide sequence encoding an amino acid sequence for HgcB from any one of the microorganisms listed in Table 1, or a consensus nucleotide sequence that detects hgcB from microorganisms capable of mercury methylation. The nucleic acids can be PCR primers, sequencing primers, hybridization probes, gene cassettes and the like.

In some embodiments of the invention, the nucleic acids are PCR primers. In such embodiments, the invention provides one or more sets of PCR primers capable of amplifying from at least about 20-25 bp to all of a microbial hgcA gene, including those listed in Table 1, wherein gene, as used herein, includes upstream and downstream regions associated with expression of the hgcA coding sequence. In alternative embodiments, the invention provides one or more sets of PCR primers capable of amplifying from at least about 20-25 bp to all of a microbial hgcB gene, including those listed in Table 1. Again, “gene” includes upstream and downstream regions associated with expression of the hgcB coding sequence.

The invention also relates to isolated recombinant expression vectors which comprise an hgcA coding sequence operably linked to a heterologous promoter, microbial cells containing that expression vector and methods of using the vector to produce HgcA by (a) culturing those cells for a time and under conditions to allow the vector to express HgcA and (b) recovering the HgcA protein. Similar recombinant expression vectors, cells and methods of use are provided for HgcB expression and for domains of HgcA or HgcB. For example, the invention includes recombinant expression vectors for production of the cobalamin-binding domain of HgcA and for mutant cobalamin-binding domains (exemplified, for example, by the C93T mutant cobalamin-binding domain in Example 4).

In further aspects of the invention, the HgcA and HgcB proteins can be used to produce and isolate polyclonal antibodies, monoclonal antibodies or immunospecific fragments thereof. Such antibodies can be used, for example, in a method to detect HgcA protein, HgcB protein or both proteins by assaying a sample for the presence of one or both of those proteins via an immunoblot, an ELISA, immunohistochemical staining and or other immunodetection technique. This method can be used, e.g., with environmental samples or with cultures of microorganisms.

Yet another aspect of the invention relates to a method to detect microorganisms capable of mercury methylation in a sample by (a) preparing nucleic acids from a sample and (b) detecting the presence of an hgcA gene, an hgcB gene, or both. In some embodiments, the sample is hybridized with one or more nucleic acid probes or primers specific for hgcA, hgcB or both and hybridization is detected by any convenient method, including, but not limited to, microarray-based assays, PCR assays, in situ hybridizations, Southern blots, or Northern blots. Any type of PCR assay can be used, including RT-PCR-based assays. The samples can be from the environment or from a clinical, microbiome-containing sample. This method can, optionally, be combined with hybridization-based methods to identify the species of microorganism in the sample.

In another method of the invention, microorganisms capable of mercury methylation can be detected by (a) preparing nucleic acids from an environmental sample and (b) sequencing that nucleic acid, in whole or in part, to detect the presence of an hgcA gene, an hgcB gene or both in the sample. In this method the nucleic acid can optionally be preselected to be specific for particular microorganisms known to methylate mercury (or to have the capacity to methylate mercury) amplified with one or more primers specific for hgcA, or hgcB or both, followed by sequencing to identify the presence of hgcA, hgcB or both in the sample.

In either of the foregoing two methods, the initial amount, or relative initial amount, of nucleic acid in the sample can be quantitatively assayed to determine the mercury methylation potential, or relative mercury methylation potential of the sample.

The present invention also provides kits for the use with any of these methods. In general, kits include probes, primers, antibodies or immunospecific fragments specific for hgcA, hgcB or both, and reagents sufficient to conduct assays to detect (qualitatively or quantitatively) hgcA, hgcB, or both, using the hgcA- or hgcB-specific reagents. For example, in one embodiment, a screening kit for detecting microorganisms capable of methylating mercury comprises (a) one or more hgcA- or hgcB-specific oligonucleotides, or both, that can be used (i) to amplify nucleic acid obtained from an environmental sample, (ii) to identify nucleic acid in the sample, or amplified from the sample, or (iii) to enable sequencing of the nucleic acid in the sample, or amplified from the sample, and reagents for conducting said screening. In some embodiments, the one or more oligonucleotides are adapted for use in a microarray format for identifying hgcA or hgcB, for a PCR assay, or for sequencing all or a portion of hgcA or hgcB-containing nucleic acid.

In yet a further aspect, the invention relates to a method of biocatalysis which comprises (a) preparing a reaction mixture comprising a methyl donor and sufficient HgcA to act as a biocatalyst in a reaction for (enantioselective) synthesis involving methyl transfer to an electrophilic organic or metal acceptor in aqueous solution.

BRIEF DESCRIPTION OF THE DRAWINGS

The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.

FIG. 1 depicts a mercury methylation cycle for bacteria and archaea. In this scheme, the methyl group originates from CH₃-THF and is transferred to cob(I)alamin-HgcA [Co(I)-HgcA] to form CH₃Co(III)-HgcA. Attack of a methyl group on HgR₂ produces CH₃HgR and cobalamin-HgcA [Co-HgcA]. The turnover cycle completes after HgcB regenerates Co(I)-HgcA. Abbreviations: THF, tetrahydrofolate.

FIG. 2 is an expanded version of the mercury methylation cycle (bold loop) in FIG. 1 showing its relationship to the reductive acetyl-CoA pathway (grey loop) and the potential sources of methyl groups.

FIG. 3 provides a structure-based amino acid sequence alignment for the cobalamin-binding domain of the corrinoid iron-sulfur protein (CFeSP) from Carboxydothermus hydrogenoformans (SEQ ID NO. 1) with HgcA from D. desulfuricans ND132 (SEQ. ID NO. 205). Only the regions producing significant sequence similarity are shown. The secondary structure diagram was derived from the crystal structure of the CfsA subunit of CFeSP (PDB: 2YCL).

FIG. 4 depicts the mercury methylation gene cluster encoding hgcA and hgcB and surrounding genome from six confirmed mercury methylators with sequenced genomes.

FIG. 5 lists the nucleotide and amino acid sequence of D. desulfuricans ND132 hgcA, SEQ ID NOS. 2 and 3, respectively.

FIG. 6 lists the nucleotide and amino acid sequence of D. desulfuricans ND132 hgcB, SEQ ID NOS. 4 and 5, respectively.

FIG. 7 shows a homology model for residues 43-166 of the cobalamin-binding domain of HgcA from D. desulfuricans ND132 constructed with the structure of CFeSP from C. hydrogenoformans as a template. Color shading indicates the degree of conservation among orthologous HgcA proteins (white/grey: low; blue/dark: high). The proximity of Cys93 to the Co center of the cobalamin cofactor suggests “Cys-on” coordination of Co in HgcA.

FIG. 8A, top, shows a sequence conservation heat map for the sequence alignments for HgcA and its orthologs in the 46 bacterial and archaeal strains listed in Table 1. The bottom panel provides the sequences for the highly conserved region from the cobalamin-binding domain, including the putative cap helix (SEQ ID NOS. 65-110, respectively, in order of appearance). The inner consensus sequence is N[V/I]WCA[A/G]GK (SEQ ID NO. 6). Residues in brackets are alternatives for the given amino acid position.

FIG. 8B is an expanded view of the Proteobacteria shown in the bottom panel of FIG. 8A.

FIG. 8C is an expanded view of the Firmicutes and Euryarcheota shown in the bottom panel of FIG. 8A.

FIG. 9A, top shows a sequence conservation heat map for the sequence alignments for HgcB and its orthologs in the 46 bacterial and archaeal strains listed in Table 1. The bottom panel provides the sequences for the three highly conserved regions: the two CX₂CX₂CX₃C (SEQ ID NO. 7) motifs characteristic of [4Fe-4S] clusters and the highly conserved vicinal pair of cysteines at the C-terminus. FIG. 9A discloses the sequences in the left column as SEQ ID NOS. 111-156, respectively, in order of appearance, the sequences in the middle column as SEQ ID NOS. 157-202, respectively, in order of appearance and “SCCG” in the right column as SEQ ID NO: 203.

FIG. 9B is an expanded view of the Proteobacteria shown in the bottom panel of FIG. 9A.

FIG. 9C is an expanded view of the Firmicutes and Euryarcheota shown in the bottom panel of FIG. 9A.

FIG. 10 provides a bar graph illustrating production of methylmercury in various D. desulfuricans ND132 (ND132) and G. sulfurreducens PCA (GSU) wild-type strains, deletion strains, complementation strains and controls. It should be noted that ΔhgcAB_(PCA) complemented with hgcA⁺ _(PCA) is still deleted for hgcB_(PCA). Bars show methylmercury concentrations (ng/L) after overnight incubation as determined by inductively-coupled plasma mass spectrometry (ICP-MS). The “Δ” prefix indicates a gene deletion and “::” indicates complementation. Values are presented as the average of triplicate assays with standard deviation. BDL is “Below Detection Limit.”

DETAILED DESCRIPTION OF THE INVENTION

A. Overview

The characterization of the genes and proteins responsible for mercury methylation, particularly in D. desulfuricans ND132 and G. sulfurreducens PCA, coupled with the extensive microbial sequence information available, enabled the identification of biomarkers, including quantifiable biomarkers, for assessing microbial mercury methylation potential. These biomarkers allow determination of direct and indirect environmental parameters that influence the degree, rate and extent of microbial methylmercury production in the environment and may inform targeted strategies for mitigating methylmercury production. The biomarkers can also be used to identify the microorganisms capable of mercury methylation, for example, as may occur in the microbiome, clinical samples, or as may be found in other sources. As used herein, “mercury methylation potential” is a measure of the capacity of a sample to produce methyl mercury. As such, it qualitatively reflects whether microorganisms capable of methylating mercury are present in a sample and, when measured quantitatively, can be used to determine how much methyl mercury can be produced in a sample or can be correlated to the number of microorganisms capable of methylating mercury present in a sample.

Prior to this invention, no specific gene or genes required for methylation of mercury had been identified. With this invention, the inventors identified two genes whose gene products are essential for mercury methylation in bacteria and archaea, facilitating methylation by a corrinoid-dependent protein and associated ferredoxin, regardless of whether or not the microbe also encodes a complete reductive acetyl-coA pathway (FIG. 1). As shown and without being bound to a mechanism, a methyl group originating from CH₃-THF (or other source) is transferred to Co(I)-HgcA to form CH₃Co(III)-HgcA followed by methyl transfer to a Hg(II) substrate (likely as a carbanion or as methyl radical) to produce methylmercury. The turnover is complete when HgcB catalyzes the reduction of the corrinoid factor to regenerate Co(I)-HgcA. FIG. 2 shows an expanded version of this mercury methylation cycle and its expected relationship to the methyl branch of the reductive acetyl-CoA pathway.

Accordingly, as disclosed herein, the genes involved in microbial mercury methylation are hgcA and hgcB. These genes and their gene products provide biomarkers for assessing environmental mercury methylation potential as well as identifying the microorganisms generating that potential, which in turn can aid in environmental mercury remediation and studies related to human health.

B. Nucleic Acids

The present invention relates to isolated nucleic acids from microbial hgcA and hgcB genes. A list of 46 sequenced microbial strains identified so far having hgcA and hgcB genes is provided in Table 1, along with the locus tag designations for hgcA and hgcB in each strain. The isolated nucleic acids of the invention include hgcA and/or hgcB from each of these strains as well as from any other microbial strains having hgcA and/or hgcB orthologs. For example, such other strains can be identified by sequencing and BLAST analysis of sequence data with any of the known hgcA or hgcB gene sequences, by hybridization of microorganismal DNA (or RNA) with hgcA or hgcB specific probes, or by PCR amplification of microbial DNA (or RNA) with hgcA or hgcB specific primers using techniques known in the art.

The isolated nucleic acids of the invention include but are not limited to, nucleic acids comprising a microbial hgcA gene, a microbial hgcB gene, or both, (which can include none, some or all of the cis-acting, transcription and expression control elements associated with the coding sequences of those genes); nucleic acids comprising the coding sequence of a microbial HgcA protein, a microbial HgcB protein, or both; expression vectors comprising a nucleic acid encoding a microbial HgcA protein, a microbial HgcB protein, or both, with or without a heterologous promoter operably linked thereto; nucleic acids of a size suitable for use as probes to detect one or more microbial hgcA genes, microbial hgcB genes, or both (typically these probes comprise from at least 14-15 nucleotides to about 50 nucleotides of contiguous hgcA or hgcB nucleotides or comprise one or more restriction fragments from a microbial hgcA or hgcB gene); and nucleic acids of a size suitable for use as primers to amplify a nucleotide fragment specifically associated with (such as an upstream or downstream region) or containing all or part of a microbial hgcA coding sequence, hgcB coding sequence, or both. The primers include PCR primers and sequencing primers. PCR primers are typically provided as forward and reverse primers, but can also be provided singly for combination with universal primers. Primer size can be varied and typically have from as few as 8-12 to as many as 20-30 contiguous hgcA- or hgcB-associated nucleotides, the size of which can readily be determined by those of skill in the art based on the purpose of the primer (PCR, sequencing, etc.). The size of fragments targeted for amplification by primers of the invention depends on the purpose for the amplification, and can range from small fragments of 15-100 bp (e.g., to clone particular sequence elements, to create mutations) to large fragments of 0.5 to 2 kb (e.g., to clone full or partial coding sequences, with or without the associated upstream and downstream sequences). Examples of PCR primers and primer sets are listed in Table 6.

Primers and probes, as well as the other nucleic acids of the invention, can be labeled with detectable markers such as enzymes, small molecules (e.g., biotin, fluorophores), and may include other nucleotides to facilitate detection, cloning, sequencing, PCR or other analysis (e.g., a primer can have a restriction site added at one end, or include barcode sequences for next generation sequencing techniques and the like).

In some embodiments, the nucleic acids of the invention comprise contiguous nucleotides from the nucleotide sequence for hgcA shown in FIG. 5 (from D. desulfuricans ND 132), a nucleotide sequence encoding the amino acid sequence for hgcA shown in FIG. 5, a nucleotide sequence encoding an amino acid sequence for hgcA from any one of the microorganisms listed in Table 1, or a consensus nucleotide sequence that specifically detects hgcA in microorganisms capable of mercury methylation. In each case, the contiguous nucleotides have a length sufficient to detect hgcA, amplify hgcA, specifically prime sequencing of hgcA and the like, consistent with the purpose or intended use of the nucleic acid as a probe, primer, and the like.

In certain embodiments, the contiguous nucleotides more specifically comprise nucleotides 256-300 shown in FIG. 5 or the equivalent nucleotides from any one of the microorganisms listed in Table 1. In some embodiments, the contiguous nucleotides more specifically comprise the nucleotides that encode amino acids 86-100 shown in FIG. 5 or the equivalent nucleotides from any one of the microorganisms listed in Table 1. In other embodiments, the contiguous nucleotides encode the consensus amino acid sequence N[V/I]WCA[A/G]GK (SEQ ID NO. 6) or TxG[I,V]N[V,I]WCA[A,G]GK[G,D,K,Q]xF, where x is any amino acid and amino acids in brackets represent alternative choices for the given position (SEQ ID NO. 8). Each of these embodiments can be further modified (e.g., to have detectable moieties) or contain additional nucleotides (to simplify detection, for PCR, for sequencing and the like). Among other uses, the nucleic acids comprising consensus sequences are particularly suited to be biomarkers for hgcA. However, any microbial-specific sequence of hgcA can serve as a biomarker for mercury methylation capacity or potential.

For hgcB, the isolated nucleic acids comprise contiguous nucleotides from the nucleotide sequence shown in FIG. 6, a nucleotide sequence encoding the amino acid sequence for hgcB shown in FIG. 6, a nucleotide sequence encoding an amino acid sequence for HgcB from any one of the microorganisms listed in Table 1, or a consensus nucleotide sequence that detects hgcB in microorganisms capable of mercury methylation. In each case, the contiguous nucleotides have a length sufficient to detect hgcB, amplify hgcB, specifically prime sequencing of hgcB and the like, consistent with the purpose of the intended use of the nucleic acid as a probe, primer, and the like.

In certain embodiments, the contiguous nucleotides from hgcB more specifically comprise nucleotides 58-90 or 148-180 shown in FIG. 6 or the equivalent nucleotides from any one of the microorganisms listed in Table 1. In some embodiments, the contiguous nucleotides more specifically comprise the nucleotides that encode amino acids 20-30 or 50-60 shown in FIG. 6 or the equivalent nucleotides from any one of the microorganisms listed in Table 1. These embodiments, as well as any microbial-specific sequence of hgcB are particularly suited to be biomarkers for hgcB and thus serve as a biomarker for mercury methylation capacity or potential.

Nucleic acids include DNA and RNA as well as chemical modifications (e.g., base or sugar modifications) and variants thereof, whether as polynucleotides or oligonucleotides.

The nucleic acids of the invention can be isolated from microorganisms or can be chemically synthesized. Methods for isolating nucleic acids from microorganisms and synthetic methods for making oligonucleotides, including probes, primers, molecular beacons, PNAs, LNAs (locked nucleic acids), etc., are well known to those of skill in the art.

The present invention also includes expression vectors which comprise any of the nucleic acids of the invention, but generally encode the entire protein sequence or a particular domain of the protein. In particular, these embodiments include expression vectors in which the coding sequence for hgcA or hgcB is operably linked to a heterologous promoter, or expression vectors in which the coding sequence for hgcA or hgcB remains operably linked to its native promoter. Expression vectors include plasmids, cosmids, viral vectors, artificial chromosomes and the like. Expression vectors can be extrachromosomal or can be integrated into the genome of an organism.

Methods for making and using isolated nucleic acids and expression vectors are well known in the art, for example, as described in Green & Sambrook (2012) Molecular Cloning: A Laboratory Manual, 4th Ed., Cold Spring Harbor Press, Cold Spring Harbor, N.Y. and its earlier editions. Likewise methods for designing and using nucleic acid probes and primers are also well known to those of skill in the art (see, for example, Innis and Gelfand, eds. (1999) PCR Methods Manual (Academic Press, New York or other texts).

C. Methods of Using Nucleic Acids of the Invention

The nucleic acids, probes, primers and expression vectors of the invention have a variety of uses relating to detecting and expressing hgcA and hgcB genes.

In some embodiments, recombinant expression vectors of the invention are used to transform microbial cells and to express HgcA, HgcB or both (for example, the two genes can be linked under control of a single operon). Accordingly, this invention includes microbial cells which comprise an expression vector of the invention. Such expression vectors include, but are not limited to, those which encode the complete protein HgcA, the complete HgcB protein or a domain thereof such as the corrinoid-binding domain of HgcA (amino acids 1-166 of the HgcA from D. desulfuricans ND132 or the analogous coding sequence from any of the strains listed in Table 1).

The microbial cells of the invention can include any strain used for expressing proteins such as E. coli and Salmonella spp. as well as others such as D. desulfuricans, G. sulfurreducens. Further, the microbial cells of the invention may be the same strain as the hgcA or hgcB gene that is being expressed. For example, if the expression vector encodes hgcA from D. desulfuricans ND 132, the microbial cell can be D. desulfuricans ND 132. Similarly, other constructs and microbial cells can be paired for protein expression.

Accordingly, another aspect of the invention provides a method of producing HgcA protein, HgcB protein, or both, by culturing a microbial cell of the invention for a time and under conditions sufficient for the vector to produce such protein. Methods of gene expression are well known in the art, see, e.g., Green & Sambrook (2012). Expression methods can use either constitutive or inducible promoters. With an inducible promoter, the cells are grown for a length of time, the promoter is induced (often with a small molecule or by a temperature shift) and the cells are cultured for another period of time to allow protein expression. Thereafter, the cells are harvested and the expressed protein (or protein domain) is recovered. The expressed products may or may not exhibit methylation activity. Inactive protein, for example, can be used for raising antibodies. Methods for protein purification and isolation are within the ken of those of skill in the art.

Yet a further aspect of the invention is directed to a method for detecting and identifying microorganisms capable of mercury methylation. In this method, nucleic acid can be extracted from a sample of the microorganism to be tested. In some instances the microorganism is isolated first or may be part of a mixture of microorganisms. The samples analyzed by these methods can be from any source, such as an unknown culture, a mixed microbial culture, a food sample, a clinical sample or an environmental sample.

The nucleic acid can be extracted as RNA or DNA, and if RNA is isolated, it can be converted to cDNA before further analysis. Typically the nucleic acids are extracted as DNA which is then analyzed by a hybridization technique such as Southern blotting (or Northern blotting, if RNA is extracted), in situ hybridization, PCR, sequencing and the like. The nucleic acid can also be analyzed by directed sequencing, where primers specific for hgcA or hgcB nucleic acid are used to capture nucleic acids, which are in turn directly sequenced.

When necessary, the nucleic acids can be amplified before detection. Additional detection methods include RT-PCR such as found in the BAX system (DuPont), deep sequencing, next generation sequencing, arrays and more. Detection methods are well known in the art. One of skill in the art can determine the appropriate primers for amplifying the hgcA/hgcB nucleic acid. A myriad of amplification and sequencing techniques are known and available in the art (see, e.g., focused genotyping, bead chips, and the next generation sequencing provided by Illumina or the 454 pyrosequencing provided by Roche), and any combination can be performed.

In one embodiment, the extracted nucleic acid can be hybridized to a microarray that contains probes specific for hgcA or hgcB, or both, from the sequences of known or suspected methylator strains (such as those listed in Table 1) or from a consensus sequence for one or both of these genes.

Additionally, the microarray can contain probes for the 16S RNA of the companion microorganisms (or other species-specific probe) to confirm identity (or to identify) the microorganism. In other words, if the microarray has a probe for hgcA DNA from D. desulfuricans ND132 and G. sulfurreducens PCA, then the microarray can also have a probe for the 16S RNA of those same two species. Further, in an embodiment designed to widely identify microorganisms having hgcA and hgcB (so to assess mercury methylation capability), the microarray can have one or more consensus sequence probes for those genes and a multiplicity of 16S RNA probes that can be used to identify the species of microorganism being tested. The multiplicity of 16S probes can number in the hundreds within the capacity of the microarray. For example, the 16S probes can include representative species expected to have mercury methylation capacity (e.g., some or all of those listed in Table 1 and other species once identified) as well as species that may not be capable of mercury methylation (but that might be found in an environmental or clinical sample) or that may serve as controls.

Additionally, some embodiments of this invention relate to detecting the mercury methylation potential in an environmental or clinical sample. The mercury methylation potential can provide a quantitative measure of the enzymatic capacity of microorganisms present in a sample to convert inorganic Hg(II) to CH₃—Hg. Hence, the greater the number of microorganisms with hgcA and hgcB genes in a sample, the greater the mercury methylation potential. The mercury methylation potential can be measured by assessing the number of microbial genomes present in a sample (detecting DNA) or by detecting and assessing gene expression activity (detecting mRNA). In either case, the level of the nucleic acid is directly proportional to the mercury methylation potential of the sample.

A variety of sampling strategies are available. For clinical samples, a swab, tissue or bodily fluid (e.g., saliva, blood, urine) sample can be obtained and processed using techniques known in the art, allowing one to assess the microbiome of humans and animals for the presence of methylators or for methylmercury potential. For example, in some instances, it may be advantageous to culture the organisms present in a clinical sample before analysis by the methods of the invention. In other instances, the sample may be used directly (or with minimal processing) in a method of the invention. Similarly, a food sample or lab culture can be obtained for use in methods of the invention.

For environmental samples, methylmercury production is known to occur anaerobically in saturated soils, wetlands, decaying periphyton mats, aquatic bottom sediment and anaerobic bottom waters. Hence, water and sediment samples are collected for qualitative and quantitative determination of the presence of microbes capable of mercury methylation. Any water source can be sampled, including but not limited to, seawater, lake water, pond water, wetlands, river water, streams, standing water and the like. Sediment samples can be obtained from any of the water sources and can be obtained from the surface or at depth. The identity and mercury methylation potential of microorganisms present in surface sedimentations are of particular interest. If necessary, the water and sediment samples can be obtained and maintained anaerobically. Techniques for obtaining water and sediment samples are known in the art. The volume of sample to be collected may vary depending on the analytical technique being used for detection and quantitation of the microbes. Volume samples can be concentrated for convenience.

The samples can be subject to size fractionation, which generally provides for different sets of organisms for analysis. For example, it may be advantageous to remove smaller viral material, or larger protists and zooplankton before analyzing the sample for the presence of microbes. Size fractionation can be achieved by using appropriate filtering techniques. The microbes of interest for identification and analysis generally range from about 0.1 to about 7 μm in size.

Once a working sample is obtained, it can be treated to extract DNA, RNA or protein using any of the myriad of techniques known in the art, including kits therefor. For example, generally, the sample is treated to lyse cells, the debris is removed and the DNA, RNA, or both, is recovered. The RNA can be converted to cDNA before analysis. Similar, if being tested, the protein in the sample can be analyzed. Since hgcA is predicted to encode a transmembrane domain, the cellular membrane fraction can be used for analysis, e.g., in an immunoblot.

Samples are analyzed by the various techniques in accordance with the methods of the invention, including but not limited to, immunological techniques, microarray analysis, molecular finger-printing, PCR, transcriptome analysis, and any of the multitude of DNA sequencing techniques available (including next generation sequencing, deep sequencing) to ascertain the presence and quantity of genes and gene products (protein or RNA) from hgcA, hgcB, or both, in the microorganisms or any nucleic acid present in the sample using the primers, probes and/or antibodies of the invention. The formats of the assays can be configured for high-throughput analysis. The analyses for hgcA/hgcB in an environmental sample can be combined with analyses for other characteristics pertinent to microorganism capable of methylating mercury, such as assessing the sample for the type of microorganisms (e.g., examining the diversity of microorganisms). For example, additional biomarkers any kits or tests of the invention can optionally include components for distinguishing whether the microorganisms are sulfate-reducing bacteria (SRB), iron-reducing bacteria and methanogens (archaea).

D. Antibodies and Protein Detection Methods

As another method for detecting HgcA, HgcB, or both, antibodies can be prepared for these proteins and used in immunodetection techniques to analyze whether samples contain one or more of these proteins. The samples are obtained as described above for nucleic acid detection methods (in Section C).

Hence, HgcA and HgcB proteins can be produced in accordance with the invention, isolated and used to prepare polyclonal antibodies or monoclonal antibodies using techniques known in the art. The genes for such antibodies can also be identified using conventional techniques. With the antibodies, immunospecific fragments thereof can be prepared by enzymatic methods. With the genes, immunogenic fragments can also be prepared by recombinant techniques known in the art.

The antibodies of the invention can be used, for example, in a method to detect HgcA protein, HgcB protein or both proteins by assaying a sample for the presence of one or both of those proteins via an immunoblot, an ELISA, immunohistochemical staining and or other immunodetection technique. Such techniques are well known in the art and such methods can be used with, e.g., environmental samples, clinical samples, food samples, cultures of microorganisms and the like.

E. Kits

A further aspect of the invention is directed screening kits for mercury methylators and for detecting mercury methylation potential in accordance with the methods of the invention. Such kits can take many forms, for example, one type of kit is designed for sequencing nucleic acid obtained from an environmental sample and/or a clinical sample. Such a kit can contain hgcA- or hgcB-specific primers (or both) to amplify the nucleic acid (either RNA or DNA) and further primers to sequence the RNA or DNA depending on the sequence technique to be used. Sequencing techniques are well known in the art, and include Sanger sequencing, 454 deep sequencing, next-generation sequencing and more. In another embodiment, the screening kit can be in a microarray format designed for detection of hgcA or hgcB DNA or RNA. In another embodiment, the screening kit can be in an ELISA format for detection of HgcA or HgcB protein (or both). Any of these kits can be combined with detection of other biomarkers or other microbial identifiers (such as 16S RNA markers).

F. Biocatalysis

The invention is further directed to a method of biocatalysis which comprises preparing an aqueous reaction mixture comprising a methyl donor, an electrophilic organic or metal acceptor, and sufficient HgcA to act as a biocatalyst for (enantioselective) synthesis, and allowing said reaction to proceed. Suitable methyl donors include but are not limited to, CH₃-THF, methyl iodide, low-potential electron donors such as a redox mediator combined with an electrode poised to provide a low potential or, in another embodiment, with photoreduction of a natural or synthetic dyes, e.g. flavins. Unlike conventional substitution reactions, which require an aprotic organic solvent, this biocatalysis can be performed in aqueous solution under anaerobic conditions.

The foregoing is considered as illustrative only of the principles of the invention. Further, since numerous modifications and changes will readily occur to those skilled in the art, it is not desired to limit the invention to the exact construction and operation shown and described, and accordingly, all suitable modifications and equivalents may be resorted to, falling within the scope of the invention. All references patents, patent applications or other documents cited are herein incorporated by reference in their entirety.

EXAMPLE 1 Identification of Hg Methylation Genes

The corrinoid iron-sulfur protein (CFeSP) from Moorella thermoacetica (Ragsdale 1987, Kung 2012) and Carboxydothermus hydrogenoformans (Svetlitchnaia 2006, Goetzl 2011) transfers a methyl group to its substrate acetyl-CoA synthase as a carbocation (CH₃ ⁺) (Banerjee 2003), suggesting that a similar corrinoid protein might stabilize the Co(III) state, enabling transfer of a methyl group to a Hg(II) substrate to yield methylmercury.

A BLAST search was performed according to Altschul (1997) using the 445 amino acid sequence of the large subunit of CFeSP from C. hydrogenoformans Z-2901 (CsfA; locus tag CHY_1223) (see also, UniProtKB: Q3ACS3; GenBank: ABB14598.1) against the translated genome sequence of the confirmed methylator D. desulfuricans ND132. The search yielded a partial match in a single gene with a sequence identity of 28% (51% similarity) for the C-terminal residues 306-441 of CFeSP (FIG. 3) with the gene in D. desulfuricans ND132 corresponding to record EGB14269.1, locus tag DND132_1056. Of note, the DND132_1056 encoded protein lacks both the TIM barrel domain and the C-terminal [4Fe-4S] binding motif of CfsA. The C-terminal region showed no detectable similarity to any proteins of known structure, but exhibited features characteristic of a transmembrane domain.

The DND132_1056 gene encodes a 338 amino acid protein with a calculated molecular weight, when combined with a cobalamin cofactor, of approximately 38 kDa, similar to the lost 40 kDa corrinoid protein (Choi 1994b). This gene and its orthologs are designated as hgcA.

Further BLAST searches using the ND132 hgcA gene against all available non-redundant CDS translations accessible through NCBI and EMBL-EBI revealed a total of 46 unique genes covering more than 50% of the query sequence with sequence identities in the range of 40-79% and E-values from 2·10⁻³⁶ to 4·10⁻¹⁴⁷ (as of September 2012). These strains, with their corresponding locus tags, are listed in Table 1.

Additional sequence analysis revealed that hgcA is part of a two-gene cluster found in D. desulfuricans ND132 and G. sulfurreducens PCA as well as other confirmed methylators (FIG. 4; Table 2). This second gene is designated hgcB and appears to be an [4Fe-4S] ferredoxin that works in tandem with hgcA to achieve mercury methylation.

The hgcA-hgcB gene cluster is present in 46 strains, including six confirmed methylators with fully sequenced genomes (Tables 1 and 2). The remaining strains listed in Table 1 can be tested for mercury methylation activity in accordance with the present invention. Further, the gene pair is absent in the eight confirmed non-methylating bacteria with sequenced genomes (Table 3).

The nucleotide and amino acid sequences for hgcA and hgcB from Desulfovibrio desulfuricans ND132 are shown in FIGS. 5 and 6, respectively. Underlined sequences are highly conserved. These genes are designated by NCBI Reference Sequence NC_016803.1. The nucleotide sequence and corresponding protein sequence for hgcA is provided as SEQ ID NO. 2 and SEQ ID NO. 3, respectively. The nucleotide sequence and corresponding protein sequence for hgcB is provided as SEQ ID NO. 4 and SEQ ID NO. 5, respectively.

Based on the data from 46 strains listed in Table 1, the consensus sequence for the cobalamin-binding domain in HgcA is TxG[I,V]N[V,I]WCA[A,G]GK[G,D,K,Q][T,L,S,A]F, where any one of the amino acids given in the brackets appears at the bracketed position, and x is any amino acid (SEQ ID NO. 204).

The genes for the cobalamin-binding protein and its associated ferredoxin-like protein are sporadically distributed among closely related organisms in two phyla of bacteria (Proteobacteria and Firmicutes) as well as in a dissimilar phylum of archaea (Euryarchaeota). At the class taxonomic level, organisms possessing the two-gene mercury methylation cluster, hgcAB, include 23 strains of Deltaproteobacteria (both SRB and FeRB), 13 Clostridia, one Negativicutes, and nine Methanomicrobia.

TABLE 1 Microbial Strains with hgcA and hgcB Genes Strain Phylum Class Locus tags (hgcA, hgcB) Desulfovibrio desulfuricans Proteobacteria Deltaproteobacteria DND132_1056, ND132 DND132_1057 Desulfovibrio aespoeensis Proteobacteria Deltaproteobacteria Daes_2662, Daes_2663 Aspo-2 Desulfovibrio africanus str. Proteobacteria Deltaproteobacteria Desaf_0117, Desaf_0115 Walvis Bay ATCC 19997 Desulfomicrobium baculatum Proteobacteria Deltaproteobacteria Dbac_0376, Dbac_0375 X DSM 4028 Desulfonatronospira Proteobacteria Deltaproteobacteria Dthio_PD1043, thiodismutans ASO3-1 Dthio_PD1042 Desulfonatronum lacustre Z- Proteobacteria Deltaproteobacteria DeslaDRAFT_0127, 7951 DSM 10312 DeslaDRAFT_0126 Desulfovibrio oxyclinae DSM Proteobacteria Deltaproteobacteria B149DRAFT_02526, 11498 B149DRAFT_02527 Desulfobulbus propionicus Proteobacteria Deltaproteobacteria Despr_0439, Despr_0438 1pr3 DSM 2032 uncultured Desulfobacterium Proteobacteria Deltaproteobacteria N47_A07900, N47_A07910 sp. Geobacter sulfurreducens Proteobacteria Deltaproteobacteria GSU1440, GSU1441 PCA DSM 12127 Geobacter metallireducens Proteobacteria Deltaproteobacteria Gmet_1240, Gmet_1241 GS-15 Geobacter sulfurreducens DL- Proteobacteria Deltaproteobacteria KN400_1466, KN400_1468 1/KN400 Geobacter metallireducens Proteobacteria Deltaproteobacteria GeomeDRAFT_0749, RCH3 GeomeDRAFT_0748 Geobacter daltonii FRC-32 Proteobacteria Deltaproteobacteria Geob_2483, Geob_2482 Geobacter sp. M18 Proteobacteria Deltaproteobacteria GM18_1031, GM18_1032 Geobacter sp. M21 Proteobacteria Deltaproteobacteria GM21_3091, GM21_3090 Geobacter uraniireducens Rf4 Proteobacteria Deltaproteobacteria Gura_0480, Gura_0481 Geobacter bemidjiensis Bem Proteobacteria Deltaproteobacteria Gbem_1183, Gbem_1184 Syntrophorhabdus Proteobacteria Deltaproteobacteria SynarDRAFT_0655, aromaticivorans UI SynarDRAFT_0656 Desulfomonile tiedjei DCB-1 Proteobacteria Deltaproteobacteria Desti_1022, Desti_1023 DSM 6799 Syntrophus aciditrophicus SB Proteobacteria Deltaproteobacteria SYN_00351, SYN_00352 delta proteobacterium MLMS-1 Proteobacteria Deltaproteobacteria MldDRAFT_0620, MldDRAFT_0621; MldDRAFT_2280, MldDRAFT_2279 delta proteobacterium NaphS2 Proteobacteria Deltaproteobacteria NPH_5533, NPH_5534 Acetivibrio cellulolyticus CD2 Firmicutes Clostridia AcelC_020100000280, AcelC_020100000285 Dehalobacter restrictus DSM Firmicutes Clostridia Dehre_1982, Dehre_1981 9455 Desulfitobacterium Firmicutes Clostridia Desde_2772, Desde_2771 dehalogenans ATCC 51507 DSM 9161 Desulfitobacterium Firmicutes Clostridia Desdi_0780, Desdi_0781 dichloroeliminans LMG P- 21439 Desulfitobacterium Firmicutes Clostridia Desme_1742, Desme_1741 metallireducens DSM 15288 Desulfitobacterium PCE1 Firmicutes Clostridia DesPCE1DRAFT_2748, DSM 10344 DesPCE1DRAFT_2747 Desulfosporosinus acidiphilus Firmicutes Clostridia Desaci_1621, Desaci_1622 SJ4 DSM 22704 Desulfosporosinus orientis Firmicutes Clostridia Desor_2652, Desor_2653 DSM 765 Desulfosporosinus sp. OT Firmicutes Clostridia DOT_5808, DOT_5807 Desulfosporosinus youngiae Firmicutes Clostridia DesyoDRAFT_4238, DSM 17734 DesyoDRAFT_4237 Ethanoligenens harbinense Firmicutes Clostridia Ethha_0975, Ethha_0976 YUAN-3 Syntrophobotulus glycolicus Firmicutes Clostridia Sgly_2352, Sgly_2351 FlGlyR DSM 8271 Dethiobacter alkaliphilus Firmicutes Clostridia DealDRAFT_3158, AHT 1 DealDRAFT_3157 Acetonema longum APO-1 Firmicutes Negativicutes ALO_18015, ALO_18010 DSM 6540 Methanofollis liminatans Euryarchaeota Methanomicrobia Metli_1685, Metli_1684 GKZPZ DSM 4140 Methanoregula boonei 6A8 Euryarchaeota Methanomicrobia Mboo_0422, Mboo_0421 Methanoregula formicicum Euryarchaeota Methanomicrobia Metfor_0951, Metfor_0952 SMSP Methanosphaerula palustris Euryarchaeota Methanomicrobia Mpal_1034, Mpal_1035 E1-9c DSM 19958 Methanospirillum hungatei Euryarchaeota Methanomicrobia Mhun_0876, Mhun_0875 JF-1 DSM 864 Methanolobus tindarius DSM Euryarchaeota Methanomicrobia MettiDRAFT_2866, 2278 MettiDRAFT_2865 Methanomethylovorans Euryarchaeota Methanomicrobia Metho_0631, Metho_0630 hollandica DSM 15978 Methanocella arvoryzae Euryarchaeota Methanomicrobia RCIX2342, RCIX2341 MRE50 (RC-1) Methanocella paludicola Euryarchaeota Methanomicrobia MCP_0718, MCP_0717 SANAE

TABLE 2 Confirmed Hg Methylating Strains with Sequenced Genomes Goldstamp Organism name ID¹ Culture collections Reference Desulfovibrio desulfurican. ND132 Gi03061 — Gilmour 2011 Desulfovibrio aespoeensis Gc01651 DSM 10631 Graham 2012 Desulfovibrio africanus Walvis Bay Gi03062 ATCC 19997, NCIB 8397 Brown 2011 Desulfobulbus propionicus 1pr3 Gc01599 DSM 2032, ATCC 33891 King 2000 Geobacter sulfurreducens PCA Gc00166 DSM 12127, ATCC 51573 Kerin 2006 Geobacter metallireducens GS-15 Gc00314 DSM 7210, ATCC 53774 Kerin 2006 ¹Goldstamp ID: Genomes OnLine Database - GOLD (Pagani 2012).

TABLE 3 Confirmed Non-methylating Strains with Sequenced Genomes Goldstamp Organism name ID¹ Culture collections Reference Desulfovibrio desulfuricans MB Gc00931 DSM 6949, Ranchou-Peyruse ATCC 27774 2009; Gilmour 2011 Desulfovibrio vulgaris Hildenborough Gc00184 DSM 644, Ranchou-Peyruse ATCC 29579 2009; Gilmour 2011 Desulfovibrio alaskensis G20 Gc00315 DSM 16109 Gilmour 2011 Desulfovibrio salexigens Gc01109 DSM 2638, Gilmour 2011 ATCC 14822 Desulfotomaculum acetoxidans Gc01106 DSM 771, ATCC 49208 Bridou 2010 Desulfotomaculum nigrificans Gi03933 DSM 574, ATCC 19998 Bridou 2010 Syntrophobacter fumaroxidans MPOB Gc00453 DSM 10017 Ranchou-Peyruse 2009 Desulfovibrio piger Gi01734 ATCC 29098, DSM 749 Graham 2012 ¹Genomes OnLine Database - GOLD (Pagani 2012)

EXAMPLE 2 Structural Analysis of HgcA and HgcB Genes

The N-terminal domain of HgcA is similar to the cobalamin-binding domain of CFeSP (PDB 2YCL; FIG. 3). Protein sequence alignment and modeling of the three-dimensional structure of the putative cobalamin-binding domain of HgcA indicated that it likely binds a corrinoid cofactor in a “5,6-dimethylbenzimidazole-off (DMB-off), histidine-off (His-off)” configuration (Ragsdale 2008a) similar to CFeSP (FIG. 7). Furthermore, alignment of the cobalamin-binding domain sequences shows a highly conserved motif, with a consensus sequence of N[V,I]WCA[A,G]GK (SEQ ID NO. 6), within the region of highest similarity to the CfsA subunit of CFeSP (FIG. 8) which is embraced within a slightly longer consensus sequence of TxG[I,V]N[V,I]WCA[A,G]GK[G,D,K,Q][T,L,S,A]F (SEQ ID NO. 204) as described in Example 1.

The lower-axial cobalt ligand in corrinoid proteins plays a role in the chemistry of Co—C bond cleavage (Banerjee, 2003). The HgcA region of highest sequence similarity to CFeSP corresponds to the cap helix, which is located near the lower-axial face of the corrin ring (Svetlitchnaia 2006). In CFeSP, the side chain of Thr374 is located within ˜3 Å of the cobalt. However, in all orthologs, a strictly conserved Cys residue (Cys93 in D. desulfuricans ND132) occupies the position corresponding to that of Thr374 in CFeSP. Although Thr374 is not considered a ligand for cobalt (Ragsdale 1987, Svetlitchnaia 2006), a Cys thiolate could be expected to coordinate strongly to Co(III) (Polson, 1997). By analogy, it appears that a lower-axial coordination of CH₃-cob(III)alamin by Cys, i.e., a “Cys-on” coordination, stabilizing the Co(III) state and enable transfer of a methyl group to Hg(II) substrates.

Identification of HgcA as a potential methyl donor to Hg(II) suggested a function for HgcB. Initial transfer of a methyl group to HgcA presumably originates from 5-methyltetrahydrofolate (CH₃-THF) (Choi, 1994b) as a CH₃ ⁺ group, catalyzed by a methyltransferase such as the CH₃-THF:CFeSP methyltransferase (MeTr) (Ragsdale 2008b) or an MeTr-like enzyme. Subsequent transfer of the methyl group to a Hg(II) substrate would require a source of electrons to enable turnover. Protein sequence analysis of the ferredoxin-like HgcB and its orthologs revealed two strictly conserved [4Fe-4S] binding motifs with the sequence CX₂CX₂CX₃C (SEQ ID NO. 7)(FIG. 9). Presence of this motif is consistent with this protein acting as the electron source. Thus, the chemistry required for Hg(II) methylation by a corrinoid protein, the presence of two [4Fe-4S] binding motifs in HgcB, and the genetic context of HgcA and HgcB and (and all pairs of respective orthologs in other known methylators), are consistent with HgcB carrying out the reduction of the corrinoid cofactor to poise HgcA to accept a CH₃ ⁺ group.

EXAMPLE 3 Functional Analysis of the hgcA and hgcB Genes and Gene Products

Deletion and Complementation Studies:

Overall Results: To establish the role of HgcA and HgcB in mercury methylation, these genes were deleted, either individually or as a pair from D. desulfuricans ND132. Additionally, the pair or hgcA alone was deleted from G. sulfurreducens PCA. Methylation activity was verified by two independent methylation assays. In each case, deletion of one or both genes resulted in abolition of mercury methylation activity by greater than 99% relative to the wild-type level. Complementation of the two-gene cluster restored 26% and 87% of wild-type activity in D. desulfuricans ND132 and G. sulfurreducens PCA, respectively, when measured by ICP-MS (FIG. 10). Deletion and subsequent complementation of hgcB alone in D. desulfuricans ND132 yielded <1% and 102% of wild-type methylation activity, respectively. Independent assays of the same strains by atomic fluorescence spectroscopy showed that complementation of the two-gene deletion in D. desulfuricans ND132 and G. sulfurreducens PCA restored 90% and 79% of wild-type activity; whereas, complementation of D. desulfuricans ND132 ΔhgcB yielded 84% of wild-type activity. Reasons for the discrepancies between the two assay methods for D. desulfuricans ND132 constructs are unclear. Complementation of either gene alone into the double deletion mutant did not restore detectable methylmercury activity. Restoration of D. desulfuricans ND132 ΔhgcA alone was not performed. Comparative growth curves with the deletion mutants showed no impairment in rate or extent of growth. Thus, under the conditions tested the construction of the deletions did not cause major growth aberrations that might interfere with the detection of methylation activity.

General: All chemicals were of analytical grade and were commercially available from Fisher Scientific (Pittsburgh, Pa.) or Sigma-Aldrich (St. Louis, Mo.). Biological reagents were from the same sources unless indicated otherwise. The bacterial strains, plasmids and primers are listed Tables 4, 5 and 6, respectively.

Culture Conditions: D. desulfuricans and G. sulfurreducens strains were cultured at 34° C. under anaerobic conditions in an anaerobic chamber (85:10:5, N₂:CO₂:H₂; Coy Laboratory Products, Inc., Grass Lake, Mich.) in MOY medium unless otherwise indicated. The MOY basal medium contained the following per liter: MgCl₂.6H₂O (1M), 8.0 ml; NH₄Cl (4M), 5 ml; CaCl₂ (1M), 0.6 ml; K₂HPO₄—NaH₂PO₄ (1M), 2.0 ml; Trace elements (Postgate, 1984), 6 ml; FeCl₂ (0.125M)/EDTA (250 mM), 50 μl; Tris-HCl (2M) pH 7.4, 15 ml; Thauer's Vitamins 10× (Brandis 1981), 1.0 ml. The yeast extract content was increased to 2.0 g per liter. In addition, titanium citrate or thioglycolate (0.38 mM or 1.2 mM final concentration, respectively) was added after sterilization to poise the redox potential of the media. The pH values of the final media were adjusted to 7.2.

D. desulfuricans ND132 was grown in MOYLS4 medium containing 30 mM sulfate and 60 mM lactate (Zane 2011) for genetic experiments. MOYLS4 medium also contained yeast extract up to 0.2% (w/v) and additionally was poised with sodium thioglycolate (1.2 mM) post-sterilization. D. desulfuricans ND132 was sensitive to kanamycin and spectinomycin at 400 μg·ml⁻¹ and 200 μg·ml⁻¹, respectively.

G. sulfurreducens PCA was grown in NBFA medium with 40 mM fumarate and 15 mM acetate (Galushko 2000; Coppi 2001).

To screen for loss of Hg-methylation, cells were grown in MOYPF medium (Gilmour 2011) containing 40 mM fumarate, 40 mM pyruvate and 1 mM cysteine (as the sole sulfur source) to limit sulfide-Hg(II) complexes (Bridou 2011).

Bacterial Plating and Growth: For plating, the top agar technique was used. Plates contained 1.5% (w/v) agar and, after pouring, were degased overnight in a hood and stored in an anaerobic jar (Mitsubishi AnaeroPack®, Thermo Scientific, USA) until use. The anaerobic top agar solution contained 0.75% (w/v) agar) and was maintained molten at 55° C. until pouring. Antibiotic used for selection/screening and reductant solutions were added to the molten agar prior to pouring plates.

Bacterial growth was monitored by measuring the optical density at 600 nm (OD₆₀₀) with a Genesys 20 spectrophotometer (Thermo Fisher, USA) or protein concentration by the Bradford method using bovine serum albumin (Sigma, St. Louis, Mo.) as standard (Bradford 1976). Spectinomycin resistant mutant D. desulfuricans ND132 (this study) containing pMO9075 (Keller 2011), was used as a positive growth control during plate selection and screening.

Molecular Biological Techniques: Molecular cloning in E. coli was conducted as described (Zane 2011) with growth aerobically in in LC medium or SOC medium, and when used, with kanamycin added at 100 μg/ml and spectinomycin at 100 μg/ml. Plasmid DNA from E. coli was prepared using a GeneJET Plasmid Miniprep Kit (Fermentas, Thermo Scientific, Glen Burnie, Md.).

PCR Techniques: PCR was performed with Herculase II polymerase (Stratagene, La Jolla, Calif.) and the primers listed in Table 6 (IDT, Coralville, Iowa). PCR products (50 μL) were treated with 20 U of DpnI and incubated at 37° C. for 1 hour. Amplified DpnI-treated DNA fragments were purified using a Wizard® SV Gel and PCR Clean-up System (Promega, USA). Agarose gel electrophoresis was conducted as described (Zane 2011).

Sequencing: Nucleotide sequences were determined using Big Dye Terminator cycle sequencing chemistry (Applied Biosystems) with a 3730×l 96-capillary DNA Analyzer. After PCR amplification, the sequences of the amplified fragment were verified against reference sequences for D. desulfuricans ND132 (GenBank accession no. NC_016803.1) and G. sulfurreducens PCA (GenBank accession no. AE017180.1).

Desulfovibrio and Geobacter Cloning and Transformation: Chromosomal DNA was purified from cultured Desulfovibrio and Geobacter strains as described (Zane 2011) except that DNA was purified with Wizard® Genomic DNA Purification Kit (Promega, USA) and eluted in sterile 18 ΩM·cm⁻¹ water (Quantum® EX, Millipore, Mass., USA).

Desulfovibrio and Geobacter strains were transformed as described for D. vulgaris Hildenborough (Keller 2011) by electroporation under anaerobic conditions with 100 μl of prepared cells and 500 μg of plasmid at 1500 V, 250Ω and 25 mF. Typical voltage and time constants of 1420 V and >1 ms were obtained for each electroporation. To increase cell recovery following electroporation, the transformed cells were resuspended in 1 ml of anaerobic MOYLS4 medium, transferred to Eppendorf tubes and incubated for 48 hours inside an anaerobic chamber with frequent inversion of the culture to re-suspend cells.

Various aliquots of the recovered cells were plated in MOYLS4 medium with kanamycin to generate ΔhgcA_(ND132), ΔhgcB_(ND132) or ΔhgcAB_(ND132) mutants. The plates were incubated for 4 to 7 days at 34° C. for ΔhgcA_(ND132), ΔhgcB_(ND132) or ΔhgcAB_(ND132) mutants, or 20 days for ΔhgcA_(PCA), and ΔhgcAB_(PCA) deletions.

Generation of Deletion Constructs: The plasmids used for the deletion of hgcA alone, hgcB alone, and the hgcA/hgcB gene cluster in D. desulfuricans ND132 and G. sulfurreducens PCA strains were constructed by SLIC sub-cloning with T4 DNA polymerase treated inserts (Li 2007) or by Gibson Assembly (Mew England BioLabs, Beverly, Mass.; Gibson 2009). Deletion of individual genes and the two-gene cluster was accomplished by amplification and assembly of four independent regions.

First, the spectinomycin resistance determinant and the pUC ori of pMO719 (Zane 2011; Keller 2011) were amplified. Second, the kanamycin resistance cassette (with its promoter) from pMO746 was generated. Note that the upp gene was also conserved in the latter cassette but was not used in these studies. Finally, the third and fourth regions were the DNA regions upstream and downstream of the targeted gene (see Tables 5 and 6).

Generation of Complementation Plasmids: Complementation of Δ(hgcB_(ND132)) and Δ(hgcAB_(ND132)) D. desulfuricans ND132 mutants and the Δ(hgcAB_(PCA)) mutant of G. sulfurreducens was achieved, respectively, by chromosomal “knock-in” of hgcB_(ND132) or hgcAB_(ND132) and hgcA_(PCA) or hgcAB_(PCA) along with a spectinomycin resistance marker that replaced the kanamycin resistance marker in the deletion mutants (Table 6). In all cases, a ˜1680 bp fragment containing the origin of replication and a partial bla gene (Ap^(R)) was amplified from pCR4/TOPO (pMO4659 and pMO4661) or pUC19 (pORNL1000 and pORNL1001) to serve as a backbone for maintenance and selection in E. coli (Table 6).

To complete the preparation of D. desulfuricans ND132 complementation constructs pMO4659 and pMO4661, a 1339 bp fragment comprised of 20 bp upstream of hgcA_(ND132) and the two genes (hgcA_(ND132) and hgcB_(ND132)), and a 2050 bp fragment containing a 731 bp upstream DNA along with both hgcAB_(ND132) was amplified from D. desulfuricans ND132, respectively. In all cases, a 789 bp region downstream from hgcB_(ND132) was amplified to flank the downstream spectinomycin resistance cassette from pMO719. The four amplicons were assembled according to the SLIC procedure (Li 2007).

In the case of G. sulfurreducens PCA, a 2103 bp fragment containing the upstream DNA along with both hgcA_(PCA) and hgcB_(PCA), or a 1797 bp fragment comprised of 762 bp upstream of the two genes along with hgcA_(PCA) was amplified from G. sulfurreducens PCA to support preparation of complementation constructs pORNL1000 and pORNL1001 respectively. The four amplicons were assembled with a Gibson Assembly Master Mix (Gibson 2009). The resulting plasmids were transformed into chemically competent E. coli DH5-α cells (BioLine), screened with PCR, sequenced, and used for transformation of the deleted mutants.

Southern Blot Analysis: Gene deletions were verified and confirmed by Southern blots (FIG. 11) as previously described (Bender 2007), using the PCR amplicon primers for the upstream region used for the deletion of the hgcA gene.

Mercury Methylation Assay: A. Measurement of Methylmercury by Ethylation Purge and Trap Gas Chromatography Atomic Fluorescence Spectroscopy (EPT-GC-AFS.)

The deletion or complementation transformants were subcultured in MOYPF medium (1% v/v) and grown to an OD₆₀₀ of ˜0.5. These cultures were diluted to a cell density of OD₆₀₀ ˜0.150 in fresh MOYPF. A 400 μL aliquot was removed into a 2 mL microcentrifuge tube, HgCl₂ was added (final concentration 10 ng/mL) and the sample was incubated in the dark for 2 hours at 34° C. After incubation, the sample was immediately acidified to a final concentration of 3N HNO₃ as described (Bridou 2011). The samples were left at room temperature for 24 hours to allow acid digestion of the cellular components followed by EPT-GC-AFS analysis as described in the following paragraph. Wild-type D. desulfuricans ND132 or G. sulfurreducens PCA was used as a positive, Hg-methylating control. Negative, Hg-non-methylating controls were heat-killed D. desulfuricans ND132, viable Desulfovibrio alaskensis G20, heat-killed D. alaskensis G20 and MOYPF as an abiotic control. Mutants were also tested as heat-killed cultures. None of the non-methylating controls methylated Hg(II) above the detection limits.

Methylmercury production was determined by EPT-GC-AFS according to EPA method 1630 (USEPA 2001). For the analysis, an 80 μl aliquot of the acidified sample was added to 40 ml Na-acetate buffer (pH 3.9). The Hg species were then ethylated with NaBEt₄ and extracted from the solution into an automated purge and trap system (MERX, Brooks Rand LLC, Seattle, Wash.) followed by gas chromatography separation and quantification by AFS with a MERX Hg speciation GC and Pyrolysis Module coupled to a Model III Cold Vapor Atomic Fluorescence Spectrophotometer (MERX, Brooks Rand LLC, Seattle, Wash.). Mercury chloride (HgCl₂) and methylmercury chloride (CH₃HgCl) used for Hg-methylation assays and external calibration, respectively, were purchased from MERX and greater than 95% pure. The analytical detection limits determined over the analysis were ≤0.52±0.1 pg/mL. Details of the analytical treatment and calculations used to determine methylmercury concentrations are provided in EPA method 1630 (USEPA 2001).

Mercury Methylation Assay: B. Measurement of Methylmercury Generation Using Stable Isotopes and ICP-MS

Mercury methylation production was also determined with enriched stable isotopes (Hintelmann 1997; Heyes 2006). At the mid-log phase of growth 10 ng/ml inorganic ²⁰¹Hg²⁺ was added to 10 ml aliquots of cell culture in N₂-purged, anaerobic, sterile Balch tubes and incubated overnight. The conversion of ²⁰¹Hg²⁺ to CH₃ ⁻ ²⁰¹Hg (1 h) was used to quantify the amount of Hg²⁺ methylated. Cultures were then preserved by adding 500 μL of 9 M H₂SO₄ and stored at 4° C. until analysis. Sample pH was verified to be <2.0 to ensure that culture buffering capacities were overcome. For total Hg quantification, samples were diluted and acidified (2% HCl with 7.5% bromine monochloride) to digest organic and cellular material.

Total Hg and CH₃Hg were measured using an automated purge and trap system (MERX, Brooks Rand LLC, Seattle, Wash.) followed by detection on an inductively-coupled plasma mass spectrometer (ICP-MS, Elan-DRCe, PerkinElmer Inc., Shelton, Conn.) using adapted EPA Methods 1630 and 1631 (USEPA 2001; USEPA 2002). Modifications to the EPA methods included the use of isotope dilution with enriched stable isotopes to determine the total Hg and CH₃Hg concentrations and detection of the Hg using ICP-MS to separate the various Hg isotopes (Hintelmann2002). For total Hg analyses, the enriched isotope (²⁰⁰Hg) was added just prior to the reduction of the Hg with stannous chloride. Enriched CH₃ ⁻ ²⁰⁰Hg, synthesized from Hg²⁺ using methylcobalamin (Hintelmann 2002), was added to the sample prior to distillation as an internal standard. Enriched Hg isotopes (purchased from Oak Ridge National Laboratory), were all greater than 95% pure and the small abundance of other isotopes was taken into account during data processing (Sturup 2005).

TABLE 4 Bacterial Strains Source or Strain Genotype Reference Escherichia coli α-Select (Bronze F-deoR endA1 recA1 relA1 gyrA96 Bioline efficiency) hsdR17(r_(k) ⁻, m_(k) ⁺) supE44 thi-1 phoA Δ(lacZYA-argF)U169 Φ80lacZAM15 λ− α-Select (Silver efficiency) F⁻ deoR endA1 recA1 relA1 gyrA96 hsdR17(r_(k) ⁻, Bioline m_(k) ⁺) supE44 thi-1 phoA Δ(lacZYA- argF)U169 Φ80lacZΔM15 λ⁻ Desulfovibrio desulfuricans ND132 Wild type Gilmour 2011 JWN1000 ND132, ΔhgcA1::(npt upp^(A)); Km^(r) This study JWN1001 ND132, Δ(hgcAB)1::(npt upp); Km^(r) This study JWN1002 ND132, ΔhgcB1::(npt upp); Km^(r) This study JWN1003 JWN1001 hgcAB⁺ aadA^(B); Km^(s), Sp^(r) This study JWN1004 JWN1002 hgcB⁺ aadA; Km^(s), Sp^(r) This study JWN1010 ND132 hgcA2(C93T)hgcB⁺ aadA; Sp^(r) This study Geobacte. sulfurreducens PCA ATCC 51573 ATCC DEGS 1000 PCA ΔhgcA1::(npt upp); Km^(r) This study DEGS 1001 PCA Δ(hgcAB)1::(npt upp); Km^(r) This study DEGS 1002 DEGS1001 hgcA⁺ ΔhgcB aadA; Sp^(r) This study DEGS 1003 DEGS1001(hgcAB)⁺ aadA; Sp^(r) This study DEGS 1004 DEGS1001 hgcB⁺ aadA; Sp^(r) This study

TABLE 5 Plasmids Source or Plasmid Characteristics Reference pCR ® 4-TOPO TOPO cloning vector; AP^(r), Km^(r) Invitrogen pUC19 Cloning vector, AP^(r, pMB1ori) Invitrogen/ GenBank L09137 pCR8/GW/TOPO TOPO cloning vector; Sp^(r) Invitrogen pMO9071 pCR8/GW/TOPO containing SRB replicon (pBG1) Zane 2011 with npt; Km^(r), Sp^(r) pMO746 upp in an artificial operon with npt from pMO9071 This study and Ap^(r)-pUC ori from pCR4/TOPO, P_(npt)-npt-upp;, Km^(r) pMO719 pCR8/GW/TOPO containing SRB replicon (pBG1); Keller 2009 Sp^(r) pMO9075 pMO719 containing P_(npt) for gene expression from Keller 2011 the plasmid in Desulfovibrio strains, Sp^(r) pMO4650 Sp^(r) and pUC ori from pMO719 plus upstream and This study downstream DNA regions from hgcA_(ND132) flanking the artificial operon of P_(npt)-npt-upp from pMO746; for marker exchange deletion mutagenesis; Sp^(r) and Km^(r) pMO4651 Sp^(r) and pUC ori from pMO719 plus upstream DNA This study region from hgcA_(ND132), the artifical operon of P_(npt)- npt-upp from pMO746 and a region from downstream hgcB_(ND132); for marker exchange deletion mutagenesis; Sp^(r) and Km^(r) pMO4652 Sp^(r) and pUC ori from pMO719 plus upstream and This study downstream DNA regions from hgcB_(ND132) flanking the artificial operon of P_(npt)-npt-upp from pMO746; for marker exchange deletion mutagenesis; Sp^(r) and Km^(r) pMO4600 pMO9075 containing P_(npt)-hgcA_(ND132), Sp^(r) This study pMO4601 pMO9075 containing P_(npt)- This study hgcB_(ND132), Sp^(r) pMO4602 pMO9075 containing P_(npt)-- This study hgcAB_(ND132), Sp^(r) pMO4659 Ap^(r)-pUC ori from pCR4/TOPO with hgcA_(ND132) and This study hgcB_(ND132) including a 20 bp region upstream from hgcA_(ND132), and a 789 bp region downstream from hgcB_(ND132) flanking the Sp^(r) cassette from pMO719; Sp^(r), Ap^(r) pMO4661 Ap^(r)-pUC ori from pCR4/TOPO with hgcA_(ND132) and This study hgcB_(ND132) including a 731 bp region upstream from hgcA_(ND132), and a 789 bp region downstream from hgcB_(ND132) flanking the Sp^(r) cassette from pMO719; Sp^(r), Ap^(r) pORNL1000 Partial bla and pMB1 ori from pUC19 with hgcA_(PCA) This study including a 762 bp upstream region, and a 995 bp region downstream from hgcB_(PCA) flanking the Sp^(r) cassette from pMO719; Sp^(r), Ap^(r) pORNL1001 Sp^(r) and pUC ori from pMO719 plus upstream DNA This study region from with hgcA_(PCA), the artificial operon of P_(npt)-npt-upp from pMO746 and a region from downstream hgcB_(PCA); for marker exchange deletion mutagenesis; Sp^(r), Km^(r) pORNL1002 Sp^(r) and pUC ori from pMO719 plus upstream DNA This study region from hgcA_(PCA), the artifical operon of _(pnpt)-npt- upp from pMO746 and a region from downstream hgcB_(PCA); for marker exchange deletion mutagenesis; Sp^(r) and Km^(r) pORNL1003 Partial bla and pMB1 ori from pUC19 with hgcA_(PCA) This study including a 762 bp region upstream from hgcA_(PCA), the Sp^(r) cassette from pMO719, and a 995 bp region downstream from hgcB_(PCA); for marker exchange insertion of hgcA_(PCA); Sp^(r) pORNL1004 Partial bla and pMB1 ori from pUC19 with hgcA_(PCA) This study and hgcBPCA including a 762 bp region upstream from hgcA_(PCA), the Sp^(r) cassette from pMO719, and a 995 bp region downstream from hgcB_(PCA); for marker exchange insertional complementation of hgcAB_(PCA); Sp^(r) pORNL1005 Partial bla and pMB1 ori from pUC19 with hgcB_(PCA) This study including a 762 bp region upstream from hgcA_(PCA), the Sp^(r) cassette from pMO719, and a 995 bp region downstream from hgcB_(PCA); for marker exchange insertion of hgcB_(PCA); Sp^(r) ^(A)The neomycin phosphotransferase II (nptII) gene was used in selection of transformed bacteria. It was initially isolated from the transposon Tn5 that was present in E. coli K12. The nptII gene codes for the aminoglycoside 3′-phosphotransferase (denoted aph(3′)-II or NPTII) enzyme. Transcription is from the P_(nptII) that also drives the transcription of upp from Desulfovibrio vulgaris Hildenborough encoding uracil phosphoribosyltransferase. This artificial operon was used in marker exchange deletion strains, although the upp was not used in these studies. ^(B)aadA encodes aminoglycoside 3′-adenyltransferase that confers spectinomycin resistance.

TABLE 6 Primers and Probes Primer Primer Sequence Primer name ID (5′->3′) Application Primers used in the deletion strategies D132-1056-upF P1_(ND132) GCCTTTTGCTGGCCTT For amplification of hgcA TTGCTCACATGTCTAC upstream region from ND132 AGGGAGCCGTTCACC gDNA with D132-1056-upR3 to (SEQ ID NO. 9) obtain pMO4650 and pM04651. Underlined portion used as overhang for SLIC with Sp^(R), pUCori fragment (Spec^(R)pUC-R). Amplification of Southern probe for confirmation of hgcA, hgcAB cluster and hgcB deletions, forward GSU-1440-upF P1_(GSU) GCCTTTTGCTGGCCTT For amplification of hgcA TTGCTCACATCTGCGT upstream region from G. CAAGGGAATGCTCCG sulfurreducens (PCA) gDNA with (SEQ ID NO. 10) GSU-1440-upR3 to obtain pORNL1001 and pORNL1002 (also referred to herein as pMO4653 and pMO4654). Underlined portion used as overhang for SLIC with Spec^(R), pUCori fragment (SpecRpUC-R). Used as forward primer for PCR and sequence based confirmation of the GSUΔ1440 and GSUΔ144- 1441 deletions D132-1056-upR3 P2_(ND132) CGACAAGATATTCGGC For amplification of hgcA ACCAAGTAAGCAAAG upstream region from ND132 GGTTCCACGGCGTAGC gDNA with D132-1056-upF from (SEQ ID NO. 11) ND132 gDNA to obtain pMO4650 and pMO4651. Underlined portion used as overhang for SLIC with Km^(R), upp fragment (Kan-Upp-Cterm-R). Amplification of Southern probe for confirmation of hgcA, hgcAB cluster and hgcB deletions. reverse GSU-1440-upR P2_(GSU) TCGCCTTCTTGACGAG For amplification of hgcA TTCTTCTGAGGTATCG upstream region from PCA AGCCAACGAAGAAAA gDNA with GSU-1440-upF to CCC obtain pORNL1001 and (SEQ ID NO. 12) pORNL1002. Underlined portion complements 5′ region of Tn5 Kan^(r) expression cassette for SLIC assembly D132-1056-dwF P5_(ND132) CCCAGCTGGCAATTCC For amplification of hgcA GGCCGGGAGACTGAT downstream region from ND132 GATGAAGGATTTCC gDNA with D132-1057-dwR (SEQ ID NO. 13) from ND132 gDNA to obtain pMO4650. Underlined portion used as overhang for SLIC with Km^(R), upp fragment (Kan-Tx-F), forward GSU-1440-dnF P5_(GSU) CCCAGCTGGCAATTCC For amplification of hgcA GGCCGGGAGGTAGCA downstream region from PCA TGATCGG gDNA with GSU1441-dnR to (SEQ ID NO. 14) obtain pORNL1001. Underlined portion complements Km^(R) expression cassette for SLIC assembly D132-1057-dwF P3_(ND132) CCCAGCTGGCAATTCC For amplification of hgcB GGTGCTGCTAGTCCGC downstream region from ND132 GAGCA gDNA with D132-1057-dwR (SEQ ID NO. 15) from ND132 gDNA to obtain pMO4651. Underlined portion used as overhang for SLIC with Km^(R), upp fragment (Kan-Tx-F), forward GSU-1441-dnF P3_(GSU) CCCAGCTGGCAATTCC For amplification of hgcB GGTGATCCATCTTGGG downstream region from PCA TGGAATTTCGTGA gDNA with GSU-1441-dnR to (SEQ ID NO. 16) obtain pORNL1002. Underlined portion used as overhang for SLIC with Km^(R), upp fragment (Kan-Tx-F), forward D132-1057-dwR P4_(ND132) CGAGGCATTTCTGTCC For amplification of hgcA TGGCTGGCCAGACGAC downstream region from ND132 GCACAGGGAAT gDNA with either D132-1056- (SEQ ID NO. 17) dwF or D132-1057-dwF to obtain pMO4650 and pMO4651, respectively. Underlined portion used as overhang for SLIC with Sp^(R), pUC ori fragment (SpecRpUC-F), reverse GSU-1441-dnR P4_(GSU) CGAGGCATTTCTGTCC For amplification of hgcAB TGGCTGGGAGATTAGC downstream region from PCA ATCGGTAGCGGCC gDNA with either GSU-1440dnF (SEQ ID NO. 18) or GSU-1441-dnF to obtain pORNL1001 and pORNL1002, respectively. Underlined portion used as overhang for SLIC with Sp^(R), pUC ori fragment (SpecRpUC-F), reverse D132-1057-upF P6_(ND132) GCCTTTTGCTGGCCTT For amplification of hgcB TTGCTCACATGCTACG upstream region from ND132 CCGTGGAACCCTTTG gDNA with D132-1057-upR to (SEQ ID NO. 19) obtain pMO4652. Underlined portion used as overhang for SLIC with Sp^(R), pUCori fragment (SpecRpUC-R), forward D132-1057-upR P7_(GSU) CGACAAGATATTCGGC For amplification of hgcB ACCAAGTAAGGGAAA upstream region from ND132 TCCTTCATCATCAGTC gDNA with D132-1057-upF from TCCCGG ND132 gDNA to obtain (SEQ ID NO. 20) pMO4652. Underlined portion used as overhang for SLIC with Km^(R), upp fragment (Kan-Upp- Cterm-R), reverse Probe_Up1440-F ACCTGCGTCAAGGGA For amplification of hgcA ATGCT upstream region from G. (SEQ ID NO. 21) sulfurreducens (PCA) gDNA with Probe_Up1440-R to obtain 783 bp upstream region of hgcA as Southern probe for confirmation of hgcA_(PCA), hgcA_(PCA)/hgcB_(PCA) cluster restoration. Probe_Up1440-R GCGTGGAGATGACCG For amplification of hgcA GCA upstream region from G. (SEQ ID NO. 22) sulfurreducens (PCA) gDNA with Probe_Up1440-F to obtain 783 bp upstream region of hgcA as Southern probe for confirmation of hgcA_(PCA), hgcA_(PCA)/hgcB_(PCA) cluster restoration. SpecRpUC-F CCAGCCAGGACAGAA For amplification of Sp^(R) and pUC ATGCCTCG ori from pMO9075 to obtain (SEQ ID NO. 23) pMO4650, pMO4651 and pMO4652. Used as overhang for SLIC, forward SpecRpUC-R ATGTGAGCAAAAGGC For amplification of Spec^(R) and CAGCAAAAGGC pUCori from pMO9075 to obtain (SEQ ID NO. 24) pMO4650, pMO4651 and pMO4652. Used as overhang for SLIC, reverse SpecRpUC-up GGGAAACGCCTGGTAT For amplification of Sp^(R) and pUC CTTTATAGTCCT ori from pMO719 to obtain (SEQ ID NO. 25) pMO4653 and pMO4654. Used as overhang for SLIC, forward Kan-Tx-F CCGGAATTGCCAGCTG For amplification of Km^(R) from GG pMO719 to obtain pMO4650, (SEQ ID NO. 26) pMO4651, pMO4652, pORNL1001 and pORNL1002. Used as overhang for SLIC, forward. Used in PCR confirmation of GSU1440 and GSU1440-1441 deletions Kan-Upp-Cterm- CTTACTTGGTGCCGAA For amplification of Km^(R) from R TATCTTGTCG pMO719 to obtain pMO4650, (SEQ ID NO. 27) pMO4651 and pMO4652. Used as overhang for SLIC, reverse Kan-R TCAGAAGAACTCGTCA For amplification of Km^(R) from AGAAGGCGA pMO719 to obtain pORNL1001 (SEQ ID NO. 28) and pORNL1002. Complements GSU1440-upR for SLIC assembly. Used in PCR confirmation of GSU1440 and GSU1440-1441 deletions pUC ori-out GGGAAACGCCTGGTAT For sequencing of the CTTTATAGT downstream regions of the (SEQ ID NO. 29) deletion cassette of plasmids pMO4650, pMO4651 and pMO4652, forward pUC ori-F GGCCTTTTGCTGGCCT For colony PCR, screen of TTTGCTCACA pMO4650, pMO4651 and (SEQ ID NO. 30) pMO4652 deletion cassette, reverse Kan-int-Fwd- CTCATCCTGTCTCTTG For sequencing of the rev-comp ATCAGATCT downstream regions of the (SEQ ID NO. 31) deletion cassette of pMO4650, pMO4651 and pMO4652, reverse DvH-Upp gene GCTGAAGCGCATCGTG For sequencing of the upstream Cterm-out GACAA regions of the deletion cassette of (SEQ ID NO. 32) pMO4650, pMO4651 and pMO4652, forward pMO719 XbaI- TGGGTTCGTGCCTTCA For colony PCR screen of Dwn TCCG pMO4650, pMO4651, pMO4652, (SEQ ID NO. 33) pMO4653, and pMO4654 and sequencing of the upstream regions of the deletion cassette of plasmids pMO4650, pMO4651, pMO4652, reverse Primers used in the complementation strategies Upstr 1056 w/ P8_(ND132) GCCTTTTGCTGGCCTT For amplification of hgcA pUC ovhg-F TTGCTCACATGTCTAC upstream region and hgcAB_(ND132) AGGGAGCCGTTCACC with 1057-Up-Spec ovhg-R to (SEQ ID NO. 34) prepare restorative constructs pMO4661 and pMO4662. Underlined portion used as overhang for SLIC assembly with Amp-pUC-F/pUC-Amp-R product. pUC ovhg_1057- P9_(ND132) GCCTTTTGCTGGCCTT For amplification of 20 bp hgcA Up-F TTGCTCACATGCTACG upstream region and hgcAB_(ND132) CCGTGGAACCCTTTG with 1057-Up-Spec ovhg-R to (SEQ ID NO. 35) prepare restorative constructs pMO4659. Underlined portion used as overhang for SLIC assembly with Amp-pUC-F/ pUC-Amp-R product. GSU1440-upF2 P8_(GSU) CAGCGTTTCTGGGTGA For amplification of hgcA GCCTGCGTCAAGGGA upstream region and GSU1440 or ATGCTCCG both GSU1440 and GSU1441 (SEQ ID NO. 36) from G. sulfurreducens (PCA) gDNA with GSU-1440-R2 or GSU1441-R2 to prepare restorative constructs pORNL1003 and pORNL1004, respectively (also referred to herein as pHg::1440 and pHg::1440-1441). Underlined portion used as overhang for Gibson assembly with pUC19oriF/pUC19AmpR product. 1057-Up-Spec P10_(ND132) AGTTGCGTGAGCGCAT For amplification of hgcA ovhg-R ACGCTACTTGCATCTA upstream region and hgcAB_(ND132) GCAGCAGGCGGCGTC with Upstr 1056 w/pUC ovhg-F GATCTTGC or GSU1441-R2 to prepare (SEQ ID NO. 37) restorative constructs pMO4659, pMO4661 and pMO4662. Underlined portion used as overhang for SLIC assembly with Spec-F/Spec-R product. GSU1440-R2 P9_(GSU) CGAGGCATTTCTGTCC For amplification of hgcA with TGGCTGGTCACCGATC GSU1440-upF2 to prepare ATGCTACCTCCCGGT pORNL1003. The overhang (SEQ ID NO. 38) region complements an upstream segment of the Sp^(R) cassette. GSU1441-R2 P10_(GSU) CGAGGCATTTCTGTCC For amplification of hgcA and TGGCTGGTCTCACGAA hgcB with GSU1440-upF2 to ATTCCACCCAAGATGG prepare complementation ATCA construct pORNL1004. The (SEQ ID NO. 39) overhang region complements an upstream segment of the Sp^(R) cassette. Spec ovhg_1056- P11_(ND132) CGAGATCACCAAGGT For amplification of 789 bp hgcB Dw-F AGTCGGCAAATAATGC downstream region with 1056- TGCTAGTCCGCGAGCA Dw-Amp ovhg-R to prepare GG restorative constructs pMO4659, (SEQ ID NO. 40) pMO4661, pMO4662 and as Southern probe for confirmation of hgcB_(ND132), hgcAB_(ND132) restoration. Underlined portion used as overhang for SLIC assembly with Spec-F/Spec-R product GSU1441-dnF2 P11_(GSU) GTAGTCGGCAAATAAC Used with GSU1441-dnR2 to CCTCGAGCTGATCCAT amplify a 995 bp segment of the CTTGGGTGGAATTTCG G. sulfurreducens PCA genome TGA located immediately downstream (SEQ ID NO. 41) of hgAB to support recombination. Underlined portion used as overhang for Gibson assembly with the downstream terminal nucleotides of the Sp^(R) cassette in pORNL1003, pORNL1004 and pORNL1005. 1056-Dw-Amp P12_(ND132) TATATACTTTAGATTG For amplification of 789 bp hgcB ovhg-R ATTTAAAACTTCCCAG downstream region with 1056- ACGACGCACAGGGAA Dw-Amp ovhg-R to prepare T restorative constructs pMO4659, (SEQ ID NO. 42) pMO4661, pMO4662 and as Southern probe for confirmation of hgcB_(ND132), hgcAB_(ND132) restoration. Underlined portion used as overhang for SLIC assembly with Amp-pUC-F/ pUC-Amp-R product. GSU1441-dnR2 P12_(GSU) GTGAGCTGATACCGCT Used with GSU1441-dnF2 to CGCGAGATTAGCATCG amplify a 995 bp segment of the GTAGCGGCC G. sulfurreducens PCA genome (SEQ ID NO. 43) located immediately downstream of hgcAB to support recombination. Underlined portion used as overhang for Gibson assembly with the pUC19 backbone segment. Amp-pUC-F GAAGTTTTAAATCAAT For amplification of a 1681 bp CTAAAGTATATATGAG fragment of pUC ori and a part of TAAACTTGGTCTGA the bla gene (Ap^(r)) to serve as a (SEQ ID NO. 44) backbone segment of pMO4659, pMO4661 and pMO4662, forward pUC19oriF GCGAGCGGTATCAGCT Used with pUC19-Amp-R for CAC amplification of a 1685 bp (SEQ ID NO. 45) fragment of pUC19 containing the ori sequence and a part of the bla gene to serve as a backbone segment of pORNL1003, pORNL1004 and pORNL1005. pUC-Amp-R ATGTGAGCAAAAGGC For amplification of a 1681 bp CAGCAAAAGG fragment containing pUC ori (SEQ ID NO. 46) sequence and a part of the bla gene (Ap^(r)) to serve as a backbone segment of pMO4659, pMO4661 and pMO4662, reverse pUC19AmpR GCTCACCCAGAAACGC Used with pUC19oriF for TG amplification of a 1685 bp (SEQ ID NO. 47) fragment of pUC19 containing the ori sequence and a part of the bla gene to serve as a backbone segment of pORNL1003, pORNL1004 and pORNL1005. Spec-F ATGCAAGTAGCGTATG For amplification of Sp^(R) marker CGCTCAC from pM0719 to obtain (SEQ ID NO. 48) pMO4659, pMO4661 and pMO4662. Used as overhang for SLIC, forward SpecRpUC-F CCAGCCAGGACAGAA Used with primer ext specRrev ATGCCTCG for amplification of a Sp^(R) marker (SEQ ID NO. 49) from pMO719 used in preparation of complementation constructs pORNL1003, pORNL1004 and pORNL1005. Spec-R TTATTTGCCGACTACC For amplification of Sp^(R) marker TTGGTGATCTCG from pMO719 to obtain (SEQ ID NO. 50) pMO4659, pMO4661 and pMO4662. Used as overhang for SLIC, reverse ext specR rev GCTCGAGGGTTATTTG Used with primer SpecRpUC-F CCGACTAC for amplification of a Sp^(R) marker (SEQ ID NO. 51) from pMO719 used in preparation of complementation constructs pORNL1003, pORNL1004 and pORNL1005. Spec-out-R3 TAACGCGCTTGCTGCT External reverse sequencing TGGA primer for the determination of (SEQ ID NO. 52) the hgcA upstream homologous recombination region and hgcAB genes of the complementation constructs pMO4659, pMO4661 and pMO4662. Spec-out-F AGCCCGTCATACTTGA External forward sequencing AGCTAGACA primer for the determination of (SEQ ID NO. 53) the hgcB downstream homologous recombination region of the complementation constructs pMO4659, pMO4661 and pMO4662. Amp-out-R2 ATGGTAAGCCCTCCCG External reverse sequencing TATCGT primer for the determination of (SEQ ID NO. 54) the hgcB downstream homologous recombination region of the complementation constructs pMO4659, pMO4661 and pMO4662. DND1056 Cys- CAACGTCTGGACCGCG Internal forward sequencing Thr F GCGGGCAA primer for the determination of (SEQ ID NO. 55) the hgcA gene of the complementation constructs pMO4659, pMO4661 and pMO4662. 1056 R interior CCTCGTCCGCCTTGTT Internal reverse sequencing Seq primer GCCGTTG primer for the determination of (SEQ ID NO. 56) the hgcA gene of the complementation constructs pMO4659, pMO4661 and pMO4662. pMO719 Xba TGGGTTCGTGCCTTCA Sequencing primer to confirm dwn TCCG inserts into pMO9075 (SEQ ID NO. 57) GSU1440-upF CTGCGTCAAGGGAATG External forward sequencing CTCCG primer for complementation (SEQ ID NO. 58) constructs pORNL1003, and pORNL1004. hgcA456F CATGATCGCGACGTCT Internal forward sequencing GC primer for complementation (SEQ ID NO. 59) constructs pORNL1003, and pORNL1004. hgcA473R GCAGACGTCCGCATCA Internal reverse sequencing TG primer for complementation (SEQ ID NO. 60) constructs pORNL1003, and pORNL1004. GSU1441-dnR GAGATTAGCATCGGTA External reverse sequencing GCGGCG primer for complementation (SEQ ID NO. 61) constructs pORNL1003, and pORNL1004. GSU1440R CCGATCATGCTACCTC External and internal reverse CCGGTC sequencing primer for (SEQ ID NO. 62) complementation constructs pORNL1003, and pORNL1004 respectively. Probe_Dw-1441- GGCATGAAGAACAGA For amplification of hgcB F AGT TCCATGGT downstream region from G. (SEQ ID NO. 63) sulfurreducens (PCA) gDNA with Probe_Up1441-R to obtain 570 bp upstream region of hgcA as Southern probe for confirmation of hgcA_(PCA), hgcA_(PCA)/hgcB_(PCA) cluster restoration. Probe_Dw-1441- GAGATTAGCATCGGTA For amplification of hgcB R GCGGCC upstream region from G. (SEQ ID NO. 64) sulfurreducens (PCA) gDNA with Probe_Up1441-F to obtain 570 bp upstream region of hgcA as Southern probe for confirmation of hgcA_(PCA), hgcA_(PCA)/hgcB_(PCA) cluster restoration.

The underlined primer's sequences correspond to the DNA overhang's regions used in the PCR fragments for SLIC or Gibson assemblages.

EXAMPLE 4 Expression and Purification of the HgcA Wild-Type and C93T Mutant Cobalamin-Binding Domains

Expression: The coding sequence for the HgcA wild-type and a C93T mutant cobalamin-binding domain (residues 1-166) of ND 132 were codon-optimized for E. coli and inserted into a pJexpress401 expression plasmid containing the T5 promoter and the kanamycin resistance gene (DNA 2.0, Inc., USA). The pJexpress401 plasmid constructs encoding the wild-type and C93T mutant cobalamin-binding domains were each transformed into E. coli BL21 cells (Novagen, USA). Cell cultures were grown in 1 L of LB broth supplemented with 0.2 M D-sorbitol and 5.0 mM betaine containing 30 μg/ml kanamycin. Cultures were grown at 37° C. to an OD₆₀₀ of 0.6 and protein expression was induced with 1 mM isopropyl β-D-1-thiogalactopyranoside (IPTG) for 3 hours with shaking at 225 rpm. The cultures were harvested by centrifugation (8,000×g, 4° C., 10 min), the bacterial cell pellets were resuspended in lysis buffer containing 50 mM Na HEPES pH 7.5, 5 mM EDTA, and 5 mM DTT (10 ml/g wet cell pellet) and stored at −80° C. The frozen cell suspensions were thawed at room temperature with stirring in the presence of 1× Halt Protease Inhibitor Cocktail (Thermo Scientific, USA) and lysed by two passes in a French Press (Thermo Spectronic, USA) at 13,000 lb/in² at 4° C. The cell debris was removed by centrifugation (20,000×g, 4° C., 45 min) and the resulting supernatant was decanted and filtered through a 0.45 μm syringe filter (Millipore, USA).

Purification: The protein purification steps were performed at room temperature using an ÄKTA Purifier system (GE Healthcare, USA) and were essentially identical for the purification of both the wild-type and C93T mutant cobalamin-binding domain of HgcA. The filtered supernatant was diluted with buffer A (25 mM Na HEPES pH 7.5, 3 mM DTT) and loaded onto a 20 ml HiLoad SP Sepharose HP column (GE Healthcare, USA) pre-quilibrated with buffer A. The protein was eluted at ˜500 mM NaCl using a linear gradient of buffer B (buffer A+1 M NaCl). The fractions containing wild-type or C93T mutant cobalamin-binding domain were pooled and loaded (6 ml injections) onto a HiPrep 26/60 Sephacryl S-100 HR gel filtration column (GE Healthcare, USA) pre-equilibrated with buffer C (25 mM Na HEPES pH 7.5, 200 mM NaCl). The gel filtration fractions corresponding to the major absorbance peak at 280 nm were pooled and homogeneity of the purified protein was confirmed by SDS-PAGE. The purified protein was concentrated using 10 kDa MWCO Amicon Ultra-15 Centrifugal Filter Units (Millipore, USA). Protein concentrations were determined by the Bradford assay using bovine serum albumin as standard.

UV/VIS Spectroscopy: To characterize the Co coordination environment in HgcA, the UV/Vis spectra were obtained for the wild-type cobalamin-binding domain of HgcA and the C93T mutant domain purified as above, in each case, with a bound aquacob(III)alamin cofactor.

Hydroxocobalamin hydrochloride was obtained from MP Biomedicals, LLC, Solon, Ohio, U.S.A. The wild-type and C93T mutant corrinoid-binding domain of HgcA_(ND132) were incubated with a five-fold molar excess of aquacobalamin in a buffer of 25 mM Na HEPES, pH 7.5 at room temperature overnight. Excess aquacobalamin was removed by ultrafiltration using 10 kDa MWCO Amicon Ultra-15 Centrifugal Filter Units (Millipore, Billerica, Mass., U.S.A.). Absorption spectra were recorded at a protein concentration of 0.42 mg/ml each for wild-type HgcA_(ND132)-CBD and C93T HgcA_(ND132)-CBD using an Agilent Cary 60 UV/Vis spectrophotometer (Agilent Technologies, Inc., Santa Clara, Calif., U.S.A.).

The C93T mutant exhibits significant shifts in the energy bands and absorption intensities relative to the wildtype, suggesting that the single-residue mutation results in a significant change in the Co coordination environment. The UV-Vis spectra are consistent with “Cys-on” coordination of the corrinoid cofactor in HgcA.

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We claim:
 1. A method which comprises (a) preparing nucleic acids from a sample; and (b) detecting the presence of an hgcA gene, an hgcB gene or both in said sample by hybridization with at least one nucleic acid probe specific for hgcA, at least one nucleic acid probe specific for hgcB, or both, wherein the at least one nucleic acid probe specific for hgcA hybridizes to a region of a nucleic acid wherein said region consists of contiguous nucleotides 256-300 of SEQ ID NO: 2, and the at least one nucleic acid probe specific for hgcB hybridizes to a region of a nucleic acid wherein said region consists of contiguous nucleotides 58-90 or 148-180 of SEQ ID NO:
 4. 2. The method of claim 1, wherein said detection is by a microarray-based assay, PCR, in situ hybridization, southern blot, or northern blot.
 3. The method of claim 1, wherein the at least one nucleic acid probe specific for hgcA and the at least one nucleic acid probe specific for hgcB are selected from the group consisting of (a) an isolated nucleic acid which comprises a fragment of contiguous hgcA or hgcB nucleotides wherein the contiguous hgcA nucleotides hybridize to a region of a nucleic acid wherein said region consists of contiguous nucleotides 256-300 of SEQ ID NO: 2, and the contiguous hgcB nucleotides hybridize to a region of a nucleic acid wherein said region consists of contiguous nucleotides 58-90 or 148-180 of SEQ ID NO: 4; (b) contiguous nucleotides selected from the group consisting of a nucleotide sequence for hgcA shown in FIG. 5 (SEQ ID NO. 2), a nucleotide sequence encoding the amino acid sequence for HgcA shown in FIG. 5 (SEQ ID. NO. 3), a nucleotide sequence encoding an amino acid sequence for HgcA from any one of the microorganisms listed in Table 1, and a consensus nucleotide sequence that detects hgcA from microorganisms capable of mercury methylation, wherein the contiguous nucleotides hybridize to a region of a nucleic acid wherein said region consists of contiguous nucleotides 256-300 of SEQ ID NO: 2; (c) contiguous nucleotides selected from the group consisting of contiguous nucleotides 256-300 shown in FIG. 5 (SEQ ID NO. 2) or the equivalent nucleotides from any one of the microorganisms listed in Table 1, the nucleotides which encode amino acids 86-100 shown in FIG. 5 (SEQ ID NO. 3) or the equivalent nucleotides from any one of the microorganisms listed in Table 1, and the nucleotides which encode the consensus amino acid sequence TxG[I,V]N[V,I]WCA[A,G]GK[G,D,K,Q]xF or the consensus amino acid sequence TxG[I,V]N[V,I]WCA[A,G]GK[G,D,K,Q][T,L,S,A]F (SEQ ID NOS. 8 or 204, respectively) where x is any amino acid and amino acids in brackets represent alternative choices for the given position, wherein the contiguous nucleotides hybridize to a region of a nucleic acid wherein said region consists of contiguous nucleotides 256-300 of SEQ ID NO: 2; (d) contiguous nucleotides selected from the group consisting of a nucleotide sequence for hgcB shown in FIG. 6 (SEQ ID NO. 4), a nucleotide sequence encoding the amino acid sequence for HgcB shown in FIG. 6 (SEQ ID NO. 5), a nucleotide sequence encoding an amino acid sequence for HgcB from any one of the microorganisms listed in Table 1, and a consensus nucleotide sequence that detects hgcB from microorganisms capable of mercury methylation, wherein the contiguous nucleotides hybridize to a region of a nucleic acid wherein said region consists of contiguous nucleotides 58-90 or 148-180 of SEQ ID NO: 4; (e) contiguous nucleotides selected from the group consisting of contiguous nucleotides 58-90 or 148-180 shown in FIG. 6 (SEQ ID NO. 4) or the equivalent nucleotides from any one of the microorganisms listed in Table 1, the nucleotides encode amino acids 20-30 or 50-60 shown in FIG. 6 (SEQ ID NO. 5) or the equivalent nucleotides from any one of the microorganisms listed in Table 1, and the equivalent nucleotides from an hgcB gene from any of the microbes in Table 1, wherein the contiguous nucleotides hybridize to a region of a nucleic acid wherein said region consists of contiguous nucleotides 58-90 or 148-180 of SEQ ID NO: 4; (f) a set of PCR primers capable of amplifying all or at least 25 bp fragment of a microbial hgcA gene, said gene including upstream and downstream regions associated with expression of the hgcA coding sequence, wherein said microbial hgcA gene is from a microorganism listed in Table 1, wherein the PCR primers hybridize to a region of a nucleic acid wherein said region consists of contiguous nucleotides 256-300 of SEQ ID NO: 2; and (g) a set of PCR primers capable of amplifying all or at least 25 bp fragment of a microbial hgcB gene, said gene including upstream and downstream regions associated with expression of the hgcB coding sequence, wherein said microbial hgcB gene is from a microorganism listed in Table 1, wherein the PCR primers hybridize to a region of a nucleic acid wherein said region consists of contiguous nucleotides 58-90 or 148-180 of SEQ ID NO:
 4. 4. The method of claim 1, wherein nucleic acid in said sample is assayed to identify the species of microorganism by performing sequencing analysis of the nucleic acid, or performing hybridization using species-specific nucleic acid probes. 